This course serves as an introduction to the structure and function of the nervous system. Emphasis is placed on the cellular properties of neurons and other excitable cells. Topics covered include the structure and biophysical properties of excitable cells, synaptic transmission, neurochemistry, neurodevelopment, and the integration of information in simple systems and the visual system.

This course includes:

Surveying the molecular and cellular mechanisms of neuronal communication.
Coversion channels in excitable membrane, synaptic transmission, and synaptic plasticity.
Correlation of the properties of ion channels and synaptic transmission with their physiological function such as learning and memory.
Discussion of the organizational principles for the formation of functional neural networks at synaptic and cellular levels.

This course reviews the processing and structure of cellular materials as they are created from polymers, metals, ceramics, glasses, and composites, develops models for the mechanical behavior of cellular solids, and shows how the unique properties of honeycombs and foams are exploited in applications such as lightweight structural panels, energy absorption devices and thermal insulation. The applications of cellular solids in medicine include increased fracture risk due to trabecular bone loss in patients with osteoporosis, the development of metal foam coatings for orthopaedic implants, and designing porous scaffolds for tissue engineering that mimic the extracellular matrix. Modelling of cellular materials applied to natural materials and biomimicking is explored. Students taking the graduate version of the class are required to complete additional assignments.

Life as an emergent property of networks of chemical reactions involving proteins and nucleic acids. Mathematical theories of metabolism, gene regulation, signal transduction, chemotaxis, excitability, motility, mitosis, development, and immunity. Applications to directed molecular evolution, DNA computing, and metabolic and genetic engineering.

This course covers cells and tissues of the immune system, lymphocyte development, the structure and function of antigen receptors, the cell biology of antigen processing and presentation, including molecular structure and assembly of MHC molecules, the biology of cytokines, leukocyte-endothelial interactions, and the pathogenesis of immunologically mediated diseases. The course is structured as a series of lectures and tutorials in which clinical cases are discussed with faculty tutors.
Lecturers
Frederick W. Alt, Marcus Altfeld, Paul Anderson, Jon C. Aster, Hugh Auchincloss, Steven P. Balk, Samuel M. Behar, Richard S. Blumberg, Francisco Bonilla, Bobby Cherayil, Benjamin Davis, David Hafler, Nir Harcohen, Bruce Horwitz, David M. Lee, Andrew Lichtman, Diane Mathis, Richard Mitchell, Hidde Ploegh, Emmett Schmidt, Arlene Sharpe, Megan Sykes, Shannon Turley, Dale T. Umetsu, Ulrich von Andrian, Bruce Walker, Kai Wucherpfennig, Ramnik Xavier, Sarah Henrickson

 Own Your History® Multimedia Anthologies -- These anthologies collect a range of materials for exploring OYH topics. They parallel and supplement the OYH school modules, available as Open Education Resources. Groups of all ages can explore & discuss these rich and varied collections for sharing reflections on aspects of U.S. history and deepening historical knowledge. They are also available through the OYH website, https://www.ownyourhistory.us/multimediaresources Until La Causa, California farmworkers lived and worked in deplorable, often inhumane, conditions, at the mercy of growers. Spanish-speaking migrant minorities, they were socially invisible to the country.  La Causa used bold nonviolent methods and community involvement to achieve change & personal dignity. Explore this history using the  links in the attachment. 

 Until La Causa, California farmworkers lived and worked in deplorable, often inhumane, conditions, at the mercy of growers. Spanish-speaking migrant minorities, they were socially invisible to the country.  La Causa used bold nonviolent methods and community involvement to achieve change & personal dignity. Explore this history using the lessons and links below.

This activity engages learners in exploring the impact of climate change on arctic sea ice in the Bering Sea. They graph and analyze sea ice extent data, conduct a lab on thermal expansion of water, and then observe how a scientist collects long-term data on a bird population.

This quick tour provides a brief introduction to ChEBI, the EBI's Chemical Entities of Biological Interest database, which focuses on 'small' chemical compounds.

By the end of the course you will be able to:
explain what the ChEBI Database is and how you can use it to access chemical compounds of interest
demonstrate where to find out more about ChEBI

Chemical Entities of Biological Interest (ChEBI) is a user-friendly online chemical dictionary that focuses on the nomenclature, structure, and biological properties of 'small' molecules that may be encountered by anyone working in molecular biology. This course will show you what kind of information is available in ChEBI and how to access and query the database.

By the end of the course you will be able to:
Evaluate what ChEBI is and how it can be useful in your day-to-day research
Know what data are stored and how ChEBI classifies molecules (understanding ChEBI ontology)
Be able to carry out different types of search

This quick tour provides a brief introduction to ChEMBL, the EMBL-EBI's chemogenomics resource.

By the end of the course you will be able to:
Describe what ChEMBL is and how it can help you to understand the interactions between drugs or drug-like molecules and their targets
Recall where to find out more about ChEMBL

This is a course for those who are interested in the challenge posed by massive and persistent world poverty, and are hopeful that economists might have something useful to say about this challenge. The questions we will take up include: Is extreme poverty a thing of the past? What is economic life like when living under a dollar per day? Why do some countries grow fast and others fall further behind? Does growth help the poor? Are famines unavoidable? How can we end child labor—or should we? How do we make schools work for poor citizens? How do we deal with the disease burden? Is micro finance invaluable or overrated? Without property rights, is life destined to be “nasty, brutish and short”? Has globalization been good to the poor? Should we leave economic development to the market? Should we leave economic development to non-governmental organizations (NGOs)? Does foreign aid help or hinder? Where is the best place to intervene?
MITx Online Version
This course is part of the Micromaster’s Program in Data, Economics, and Design of Policy through MITx Online. The course is entirely free to audit, though learners have the option to pay a fee, which is based on the learner’s ability to pay, to take the proctored exam, and earn a course certificate. To access the course, create an MITx Online account and enroll in the course 14.73x The Challenges of Global Poverty.

How would you like to travel to new places while collaborating on a geospatial data challenge with students from around the world? In this class, students collaborate on a global-scale geospatial analysis problem with a focus on data analytics and professional practice in Geographic Information Systems. Penn State MGIS students collaborate with graduate students from ITC - University of Twente in Enschede, Netherlands to develop solutions to analyze spatio-temporal patterns in refugee migration data. Students have the opportunity to present their work and develop new connections with EU geospatial professionals via site visits to European national mapping agencies. Students work in teams to use geospatial analytics to arrive at a solution to visualize patterns over space and time.

The Chandra Astrophysics Institute (CAI), a Chandra X-ray Observatory–sponsored program run by the MIT Kavli Institute for Astrophysics and Space Research, was intended for students from the Boston area from a wide range of academic backgrounds with a limited opportunity to directly experience authentic science. 
The CAI was a year-long program to train for and take part in authentic astronomy projects. Participants built employable research, technology, and collaboration skills and the background knowledge necessary to understand how research science is done. Investigations of different astronomical systems were undertaken during a five-week summer session at MIT. Participants, mentored by MIT researchers and educators, then applied these skills to undertake research projects in x-ray astronomy based on observations made with the Chandra X-Ray Observatory.

“Change the World via The Literary Research Paper” is a course framework for composition. This course framework incorporates a semester-long group project that empowers students to make connections and choices to leverage Literature research to make changes in their community. It also provides learners with the opportunity to explore their interests and apply research from literature, social issues, non-profit organizations, or civic groups.

In this course, students will develop their abilities to expose ways that scientific knowledge has been shaped in contexts that are gendered, racialized, economically exploitative, and hetero-normative. This happens through a sequence of four projects that concern:

Interpretation of the cultural dimension of sciences
Climate change futures
Genomic citizenry
Students’ plans for ongoing practice

The course uses a Project-Based Learning format that allows students to shape their own directions of inquiry in each project, development of skills, and collegial support. Students’ learning will be guided by individualized bibliographies co-constructed with the instructors, the inquiries of the other students, and a set of tools and processes for literary analysis, inquiry, reflection, and support. 
Acknowledgement
Professor Peter Taylor spent several years crafting the unique structure of the course, which is crucial to the way it was taught. 
The Consortium for Graduate Studies in Gender, Culture, Women, and Sexuality
This course was taught as part of the Consortium for Graduate Studies in Gender, Culture, Women, and Sexuality (GCWS) at MIT. The GCWS brings together scholars and teachers at nine degree-granting institutions in the Boston area who are devoted to graduate teaching and research in Women’s Studies and to advance interdisciplinary Women’s Studies scholarship.

Each year, groups of MIT freshmen are introduced to MIT’s laboratory environment through a four-week intensive January course called 5.301 Chemistry Lab Techniques. The stakes are high—students who pass the class are guaranteed a job in an MIT research lab. 
OpenCourseWare documented the experience of 14 students who took this course in January 2012. Follow their journey over 11 episodes and watch as they struggled with, but ultimately mastered, the techniques needed to be successful in an MIT chemistry lab.
WARNING NOTICE
The experiments described in these materials are potentially hazardous. Among other things, the experiments should include the following safety measures: a high level of safety training, special facilities and equipment, the use of proper personal protective equipment, and supervision by appropriate individuals. You bear the sole responsibility, liability, and risk for the implementation of such safety procedures and measures. MIT and Dow shall have no responsibility, liability, or risk for the content or implementation of any of the material presented. Legal Notice

This course aims to connect the principles, concepts, and laws/postulates of classical and statistical thermodynamics to applications that require quantitative knowledge of thermodynamic properties from a macroscopic to a molecular level. It covers their basic postulates of classical thermodynamics and their application to transient open and closed systems, criteria of stability and equilibria, as well as constitutive property models of pure materials and mixtures emphasizing molecular-level effects using the formalism of statistical mechanics. Phase and chemical equilibria of multicomponent systems are covered. Applications are emphasized through extensive problem work relating to practical cases.

This is an undergraduate introductory laboratory subject in ocean chemistry and measurement. There are three main elements to the course: oceanic chemical sampling and analysis, instrumentation development for the ocean environment, and the larger field of ocean science.
This course is offered through The MIT/WHOI Joint Program. The MIT/WHOI Joint Program is one of the premier marine science graduate programs in the world. It draws on the complementary strengths and approaches of two great institutions: the Massachusetts Institute of Technology (MIT) and the Woods Hole Oceanographic Institution (WHOI).

Introduction to the fundamental principles of chemistry including atomic structure, stoichiometry, the periodic table of the elements, chemical bonding, molecular structure, and states of matter based on kinetic theory. This course is intended for majors in any of the sciences, including pre-dental, pre-medical, and pre-engineering students